/*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright (c) 2019 Conrad Meyer * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include __FBSDID("$FreeBSD$"); #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * Timer-based reseed interval growth factor and limit in seconds. (§ 3.2) */ #define FXENT_RESSED_INTVL_GFACT 3 #define FXENT_RESEED_INTVL_MAX 3600 /* * Pool reseed schedule. Initially, only pool 0 is active. Until the timer * interval reaches INTVL_MAX, only pool 0 is used. * * After reaching INTVL_MAX, pool k is either activated (if inactive) or used * (if active) every 3^k timer reseeds. (§ 3.3) * * (Entropy harvesting only round robins across active pools.) */ #define FXENT_RESEED_BASE 3 /* * Number of bytes from high quality sources to allocate to pool 0 before * normal round-robin allocation after each timer reseed. (§ 3.4) */ #define FXENT_HI_SRC_POOL0_BYTES 32 /* * § 3.1 * * Low sources provide unconditioned entropy, such as mouse movements; high * sources are assumed to provide high-quality random bytes. Pull sources are * those which can be polled, i.e., anything randomdev calls a "random_source." * * In the whitepaper, low sources are pull. For us, at least in the existing * design, low-quality sources push into some global ring buffer and then get * forwarded into the RNG by a thread that continually polls. Presumably their * design batches low entopy signals in some way (SHA512?) and only requests * them dynamically on reseed. I'm not sure what the benefit is vs feeding * into the pools directly. */ enum fxrng_ent_access_cls { FXRNG_PUSH, FXRNG_PULL, }; enum fxrng_ent_source_cls { FXRNG_HI, FXRNG_LO, FXRNG_GARBAGE, }; struct fxrng_ent_cls { enum fxrng_ent_access_cls entc_axx_cls; enum fxrng_ent_source_cls entc_src_cls; }; static const struct fxrng_ent_cls fxrng_hi_pull = { .entc_axx_cls = FXRNG_PULL, .entc_src_cls = FXRNG_HI, }; static const struct fxrng_ent_cls fxrng_hi_push = { .entc_axx_cls = FXRNG_PUSH, .entc_src_cls = FXRNG_HI, }; static const struct fxrng_ent_cls fxrng_lo_push = { .entc_axx_cls = FXRNG_PUSH, .entc_src_cls = FXRNG_LO, }; static const struct fxrng_ent_cls fxrng_garbage = { .entc_axx_cls = FXRNG_PUSH, .entc_src_cls = FXRNG_GARBAGE, }; /* * This table is a mapping of randomdev's current source abstractions to the * designations above; at some point, if the design seems reasonable, it would * make more sense to pull this up into the abstraction layer instead. */ static const struct fxrng_ent_char { const struct fxrng_ent_cls *entc_cls; } fxrng_ent_char[ENTROPYSOURCE] = { [RANDOM_CACHED] = { .entc_cls = &fxrng_hi_push, }, [RANDOM_ATTACH] = { .entc_cls = &fxrng_lo_push, }, [RANDOM_KEYBOARD] = { .entc_cls = &fxrng_lo_push, }, [RANDOM_MOUSE] = { .entc_cls = &fxrng_lo_push, }, [RANDOM_NET_TUN] = { .entc_cls = &fxrng_lo_push, }, [RANDOM_NET_ETHER] = { .entc_cls = &fxrng_lo_push, }, [RANDOM_NET_NG] = { .entc_cls = &fxrng_lo_push, }, [RANDOM_INTERRUPT] = { .entc_cls = &fxrng_lo_push, }, [RANDOM_SWI] = { .entc_cls = &fxrng_lo_push, }, [RANDOM_FS_ATIME] = { .entc_cls = &fxrng_lo_push, }, [RANDOM_UMA] = { .entc_cls = &fxrng_lo_push, }, [RANDOM_PURE_OCTEON] = { .entc_cls = &fxrng_hi_push, /* Could be made pull. */ }, [RANDOM_PURE_SAFE] = { .entc_cls = &fxrng_hi_push, }, [RANDOM_PURE_GLXSB] = { .entc_cls = &fxrng_hi_push, }, [RANDOM_PURE_HIFN] = { .entc_cls = &fxrng_hi_push, }, [RANDOM_PURE_RDRAND] = { .entc_cls = &fxrng_hi_pull, }, [RANDOM_PURE_NEHEMIAH] = { .entc_cls = &fxrng_hi_pull, }, [RANDOM_PURE_RNDTEST] = { .entc_cls = &fxrng_garbage, }, [RANDOM_PURE_VIRTIO] = { .entc_cls = &fxrng_hi_pull, }, [RANDOM_PURE_BROADCOM] = { .entc_cls = &fxrng_hi_push, }, [RANDOM_PURE_CCP] = { .entc_cls = &fxrng_hi_pull, }, [RANDOM_PURE_DARN] = { .entc_cls = &fxrng_hi_pull, }, [RANDOM_PURE_TPM] = { .entc_cls = &fxrng_hi_push, }, [RANDOM_PURE_VMGENID] = { .entc_cls = &fxrng_hi_push, }, }; /* Useful for single-bit-per-source state. */ BITSET_DEFINE(fxrng_bits, ENTROPYSOURCE); /* XXX Borrowed from not-yet-committed D22702. */ #ifndef BIT_TEST_SET_ATOMIC_ACQ #define BIT_TEST_SET_ATOMIC_ACQ(_s, n, p) \ (atomic_testandset_acq_long( \ &(p)->__bits[__bitset_word((_s), (n))], (n)) != 0) #endif #define FXENT_TEST_SET_ATOMIC_ACQ(n, p) \ BIT_TEST_SET_ATOMIC_ACQ(ENTROPYSOURCE, n, p) /* For special behavior on first-time entropy sources. (§ 3.1) */ static struct fxrng_bits __read_mostly fxrng_seen; /* For special behavior for high-entropy sources after a reseed. (§ 3.4) */ _Static_assert(FXENT_HI_SRC_POOL0_BYTES <= UINT8_MAX, ""); static uint8_t __read_mostly fxrng_reseed_seen[ENTROPYSOURCE]; /* Entropy pools. Lock order is ENT -> RNG(root) -> RNG(leaf). */ static struct mtx fxent_pool_lk; MTX_SYSINIT(fx_pool, &fxent_pool_lk, "fx entropy pool lock", MTX_DEF); #define FXENT_LOCK() mtx_lock(&fxent_pool_lk) #define FXENT_UNLOCK() mtx_unlock(&fxent_pool_lk) #define FXENT_ASSERT(rng) mtx_assert(&fxent_pool_lk, MA_OWNED) #define FXENT_ASSERT_NOT(rng) mtx_assert(&fxent_pool_lk, MA_NOTOWNED) static struct fxrng_hash fxent_pool[FXRNG_NPOOLS]; static unsigned __read_mostly fxent_nactpools = 1; static struct timeout_task fxent_reseed_timer; static int __read_mostly fxent_timer_ready; /* * Track number of bytes of entropy harvested from high-quality sources prior * to initial keying. The idea is to collect more jitter entropy when fewer * high-quality bytes were available and less if we had other good sources. We * want to provide always-on availability but don't necessarily have *any* * great sources on some platforms. * * Like fxrng_ent_char: at some point, if the design seems reasonable, it would * make more sense to pull this up into the abstraction layer instead. * * Jitter entropy is unimplemented for now. */ static unsigned long fxrng_preseed_ent; void fxrng_pools_init(void) { size_t i; for (i = 0; i < nitems(fxent_pool); i++) fxrng_hash_init(&fxent_pool[i]); } static inline bool fxrng_hi_source(enum random_entropy_source src) { return (fxrng_ent_char[src].entc_cls->entc_src_cls == FXRNG_HI); } /* * A racy check that this high-entropy source's event should contribute to * pool0 on the basis of per-source byte count. The check is racy for two * reasons: * - Performance: The vast majority of the time, we've already taken 32 bytes * from any present high quality source and the racy check lets us avoid * dirtying the cache for the global array. * - Correctness: It's fine that the check is racy. The failure modes are: * • False positive: We will detect when we take the lock. * • False negative: We still collect the entropy; it just won't be * preferentially placed in pool0 in this case. */ static inline bool fxrng_hi_pool0_eligible_racy(enum random_entropy_source src) { return (atomic_load_acq_8(&fxrng_reseed_seen[src]) < FXENT_HI_SRC_POOL0_BYTES); } /* * Top level entropy processing API from randomdev. * * Invoked by the core randomdev subsystem both for preload entropy, "push" * sources (like interrupts, keyboard, etc) and pull sources (RDRAND, etc). */ void fxrng_event_processor(struct harvest_event *event) { enum random_entropy_source src; unsigned pool; bool first_time, first_32; src = event->he_source; ASSERT_DEBUG(event->he_size <= sizeof(event->he_entropy), "%s: he_size: %u > sizeof(he_entropy): %zu", __func__, (unsigned)event->he_size, sizeof(event->he_entropy)); /* * Zero bytes of source entropy doesn't count as observing this source * for the first time. We still harvest the counter entropy. */ first_time = event->he_size > 0 && !FXENT_TEST_SET_ATOMIC_ACQ(src, &fxrng_seen); if (__predict_false(first_time)) { /* * "The first time [any source] provides entropy, it is used to * directly reseed the root PRNG. The entropy pools are * bypassed." (§ 3.1) * * Unlike Windows, we cannot rely on loader(8) seed material * being present, so we perform initial keying in the kernel. * We use brng_generation 0 to represent an unkeyed state. * * Prior to initial keying, it doesn't make sense to try to mix * the entropy directly with the root PRNG state, as the root * PRNG is unkeyed. Instead, we collect pre-keying dynamic * entropy in pool0 and do not bump the root PRNG seed version * or set its key. Initial keying will incorporate pool0 and * bump the brng_generation (seed version). * * After initial keying, we do directly mix in first-time * entropy sources. We use the root BRNG to generate 32 bytes * and use fxrng_hash to mix it with the new entropy source and * re-key with the first 256 bits of hash output. */ FXENT_LOCK(); FXRNG_BRNG_LOCK(&fxrng_root); if (__predict_true(fxrng_root.brng_generation > 0)) { /* Bypass the pools: */ FXENT_UNLOCK(); fxrng_brng_src_reseed(event); FXRNG_BRNG_ASSERT_NOT(&fxrng_root); return; } /* * Keying the root PRNG requires both FXENT_LOCK and the PRNG's * lock, so we only need to hold on to the pool lock to prevent * initial keying without this entropy. */ FXRNG_BRNG_UNLOCK(&fxrng_root); /* Root PRNG hasn't been keyed yet, just accumulate event. */ fxrng_hash_update(&fxent_pool[0], &event->he_somecounter, sizeof(event->he_somecounter)); fxrng_hash_update(&fxent_pool[0], event->he_entropy, event->he_size); if (fxrng_hi_source(src)) { /* Prevent overflow. */ if (fxrng_preseed_ent <= ULONG_MAX - event->he_size) fxrng_preseed_ent += event->he_size; } FXENT_UNLOCK(); return; } /* !first_time */ /* * "The first 32 bytes produced by a high entropy source after a reseed * from the pools is always put in pool 0." (§ 3.4) * * The first-32-byte tracking data in fxrng_reseed_seen is reset in * fxent_timer_reseed_npools() below. */ first_32 = event->he_size > 0 && fxrng_hi_source(src) && atomic_load_acq_int(&fxent_nactpools) > 1 && fxrng_hi_pool0_eligible_racy(src); if (__predict_false(first_32)) { unsigned rem, seen; FXENT_LOCK(); seen = fxrng_reseed_seen[src]; if (seen == FXENT_HI_SRC_POOL0_BYTES) goto round_robin; rem = FXENT_HI_SRC_POOL0_BYTES - seen; rem = MIN(rem, event->he_size); fxrng_reseed_seen[src] = seen + rem; /* * We put 'rem' bytes in pool0, and any remaining bytes are * round-robin'd across other pools. */ fxrng_hash_update(&fxent_pool[0], ((uint8_t *)event->he_entropy) + event->he_size - rem, rem); if (rem == event->he_size) { fxrng_hash_update(&fxent_pool[0], &event->he_somecounter, sizeof(event->he_somecounter)); FXENT_UNLOCK(); return; } /* * If fewer bytes were needed than this even provied, We only * take the last rem bytes of the entropy buffer and leave the * timecounter to be round-robin'd with the remaining entropy. */ event->he_size -= rem; goto round_robin; } /* !first_32 */ FXENT_LOCK(); round_robin: FXENT_ASSERT(); pool = event->he_destination % fxent_nactpools; fxrng_hash_update(&fxent_pool[pool], event->he_entropy, event->he_size); fxrng_hash_update(&fxent_pool[pool], &event->he_somecounter, sizeof(event->he_somecounter)); if (__predict_false(fxrng_hi_source(src) && atomic_load_acq_64(&fxrng_root_generation) == 0)) { /* Prevent overflow. */ if (fxrng_preseed_ent <= ULONG_MAX - event->he_size) fxrng_preseed_ent += event->he_size; } FXENT_UNLOCK(); } /* * Top level "seeded" API/signal from randomdev. * * This is our warning that a request is coming: we need to be seeded. In * fenestrasX, a request for random bytes _never_ fails. "We (ed: ditto) have * observed that there are many callers that never check for the error code, * even if they are generating cryptographic key material." (§ 1.6) * * If we returned 'false', both read_random(9) and chacha20_randomstir() * (arc4random(9)) will blindly charge on with something almost certainly worse * than what we've got, or are able to get quickly enough. */ bool fxrng_alg_seeded(void) { uint8_t hash[FXRNG_HASH_SZ]; sbintime_t sbt; /* The vast majority of the time, we expect to already be seeded. */ if (__predict_true(atomic_load_acq_64(&fxrng_root_generation) != 0)) return (true); /* * Take the lock and recheck; only one thread needs to do the initial * seeding work. */ FXENT_LOCK(); if (atomic_load_acq_64(&fxrng_root_generation) != 0) { FXENT_UNLOCK(); return (true); } /* XXX Any one-off initial seeding goes here. */ fxrng_hash_finish(&fxent_pool[0], hash, sizeof(hash)); fxrng_hash_init(&fxent_pool[0]); fxrng_brng_reseed(hash, sizeof(hash)); FXENT_UNLOCK(); randomdev_unblock(); explicit_bzero(hash, sizeof(hash)); /* * This may be called too early for taskqueue_thread to be initialized. * fxent_pool_timer_init will detect if we've already unblocked and * queue the first timer reseed at that point. */ if (atomic_load_acq_int(&fxent_timer_ready) != 0) { sbt = SBT_1S; taskqueue_enqueue_timeout_sbt(taskqueue_thread, &fxent_reseed_timer, -sbt, (sbt / 3), C_PREL(2)); } return (true); } /* * Timer-based reseeds and pool expansion. */ static void fxent_timer_reseed_npools(unsigned n) { /* * 64 * 8 => moderately large 512 bytes. Could be static, as we are * only used in a static context. On the other hand, this is in * threadqueue TASK context and we're likely nearly at top of stack * already. */ uint8_t hash[FXRNG_HASH_SZ * FXRNG_NPOOLS]; unsigned i; ASSERT_DEBUG(n > 0 && n <= FXRNG_NPOOLS, "n:%u", n); FXENT_ASSERT(); /* * Collect entropy from pools 0..n-1 by concatenating the output hashes * and then feeding them into fxrng_brng_reseed, which will hash the * aggregate together with the current root PRNG keystate to produce a * new key. It will also bump the global generation counter * appropriately. */ for (i = 0; i < n; i++) { fxrng_hash_finish(&fxent_pool[i], hash + i * FXRNG_HASH_SZ, FXRNG_HASH_SZ); fxrng_hash_init(&fxent_pool[i]); } fxrng_brng_reseed(hash, n * FXRNG_HASH_SZ); explicit_bzero(hash, n * FXRNG_HASH_SZ); /* * "The first 32 bytes produced by a high entropy source after a reseed * from the pools is always put in pool 0." (§ 3.4) * * So here we reset the tracking (somewhat naively given the majority * of sources on most machines are not what we consider "high", but at * 32 bytes it's smaller than a cache line), so the next 32 bytes are * prioritized into pool0. * * See corresponding use of fxrng_reseed_seen in fxrng_event_processor. */ memset(fxrng_reseed_seen, 0, sizeof(fxrng_reseed_seen)); FXENT_ASSERT(); } static void fxent_timer_reseed(void *ctx __unused, int pending __unused) { static unsigned reseed_intvl_sec = 1; /* Only reseeds after FXENT_RESEED_INTVL_MAX is achieved. */ static uint64_t reseed_number = 1; unsigned next_ival, i, k; sbintime_t sbt; if (reseed_intvl_sec < FXENT_RESEED_INTVL_MAX) { next_ival = FXENT_RESSED_INTVL_GFACT * reseed_intvl_sec; if (next_ival > FXENT_RESEED_INTVL_MAX) next_ival = FXENT_RESEED_INTVL_MAX; FXENT_LOCK(); fxent_timer_reseed_npools(1); FXENT_UNLOCK(); } else { /* * The creation of entropy pools beyond 0 is enabled when the * reseed interval hits the maximum. (§ 3.3) */ next_ival = reseed_intvl_sec; /* * Pool 0 is used every reseed; pool 1..0 every 3rd reseed; and in * general, pool n..0 every 3^n reseeds. */ k = reseed_number; reseed_number++; /* Count how many pools, from [0, i), to use for reseed. */ for (i = 1; i < MIN(fxent_nactpools + 1, FXRNG_NPOOLS); i++) { if ((k % FXENT_RESEED_BASE) != 0) break; k /= FXENT_RESEED_BASE; } /* * If we haven't activated pool i yet, activate it and only * reseed from [0, i-1). (§ 3.3) */ FXENT_LOCK(); if (i == fxent_nactpools + 1) { fxent_timer_reseed_npools(fxent_nactpools); fxent_nactpools++; } else { /* Just reseed from [0, i). */ fxent_timer_reseed_npools(i); } FXENT_UNLOCK(); } /* Schedule the next reseed. */ sbt = next_ival * SBT_1S; taskqueue_enqueue_timeout_sbt(taskqueue_thread, &fxent_reseed_timer, -sbt, (sbt / 3), C_PREL(2)); reseed_intvl_sec = next_ival; } static void fxent_pool_timer_init(void *dummy __unused) { sbintime_t sbt; TIMEOUT_TASK_INIT(taskqueue_thread, &fxent_reseed_timer, 0, fxent_timer_reseed, NULL); if (atomic_load_acq_64(&fxrng_root_generation) != 0) { sbt = SBT_1S; taskqueue_enqueue_timeout_sbt(taskqueue_thread, &fxent_reseed_timer, -sbt, (sbt / 3), C_PREL(2)); } atomic_store_rel_int(&fxent_timer_ready, 1); } /* After taskqueue_thread is initialized in SI_SUB_TASKQ:SI_ORDER_SECOND. */ SYSINIT(fxent_pool_timer_init, SI_SUB_TASKQ, SI_ORDER_ANY, fxent_pool_timer_init, NULL);